Abstract: A metrology target includes a first set of pattern elements compatible with a first metrology mode along one or more directions, and a second set of pattern elements compatible with a second metrology mode along one or more directions, wherein the second set of pattern elements includes a first portion of the first set of pattern elements, and wherein the second set of pattern elements is surrounded by a second portion of the first set of pattern elements not included in the second set of pattern elements.

Abstract: A semiconductor substrate is provided in which an alignment mark is formed that can be used for an alignment even after the formation of an impurity diffused layer by the planarization of an epitaxial film. A trench is formed in an alignment region of an N?-type layer formed on an N+-type substrate. This trench is used to leave voids after the formation of a P?-type epitaxial film on the N?-type layer. Then, the voids formed in the N?-type layer can be used as an alignment mark. Thus, such a semiconductor substrate can be used to provide an alignment in the subsequent step of manufacturing the semiconductor apparatus. Thus, the respective components constituting the semiconductor apparatus can be formed at desired positions accurately.

Abstract: Methods are provided for using masking techniques and plasma etching techniques to dice a compound semiconductor wafer into dies. Using these methods allows compound semiconductor die to be obtained that have smooth side walls, a variety of shapes and dimensions, and a variety of side wall profiles. In addition, by using these techniques to perform the dicing operations, the locations of features of the die relative to the side walls are ascertainable with certainty such that one or more of the side walls can be used as a passive alignment feature to precisely align one or more of the die with an external device.

Abstract: By forming a trench isolation structure after providing a high-k dielectric layer stack, direct contact of oxygen-containing insulating material of a top surface of the trench isolation structure with the high-k dielectric material in shared polylines may be avoided. This technique is self-aligned, thereby enabling further device scaling without requiring very tight lithography tolerances. After forming the trench isolation structure, the desired electrical connection across the trench isolation structure may be re-established by providing a further conductive material.

Abstract: Integrating a semiconductor component with a substrate through a low loss interconnection formed through adaptive patterning includes forming a cavity in the substrate, placing the semiconductor component therein, filling a gap between the semiconductor component and substrate with a fill of same or similar dielectric constant as that of the substrate and adaptively patterning a low loss interconnection on the fill and extending between the contacts of the semiconductor component and the electrical traces on the substrate. The contacts and leads are located and adjoined using an adaptive patterning technique that places and forms a low loss radio frequency transmission line that compensates for any misalignment between the semiconductor component contacts and the substrate leads.

Abstract: A semiconductor substrate is provided in which an alignment mark is formed that can be used for an alignment even after the formation of an impurity diffused layer by the planarization of an epitaxial film. A trench is formed in an alignment region of an N?-type layer formed on an N+-type substrate. This trench is used to leave voids after the formation of a P?-type epitaxial film on the N?-type layer. Then, the voids formed in the N?-type layer can be used as an alignment mark. Thus, such a semiconductor substrate can be used to provide an alignment in the subsequent step of manufacturing the semiconductor apparatus. Thus, the respective components constituting the semiconductor apparatus can be formed at desired positions accurately.

Abstract: The present disclosure relates to methods of forming a self-aligned contact and related apparatus. In some embodiments, the method forms a plurality of gate lines interspersed between a plurality of dielectric lines, wherein the gate lines and the dielectric lines extend in a first direction over an active area. One or more of the plurality of gate lines are into a plurality of gate line sections aligned in the first direction. One or more of the plurality of dielectric lines are cut into a plurality of dielectric lines sections aligned in the first direction. A dummy isolation material is deposited between adjacent dielectric sections in the first direction and between adjacent gate line sections in the first direction. One or more self-aligned metal contacts are then formed by replacing a part of one or more of the plurality of dielectric lines over the active area with a contact metal.

Abstract: A solid-state image pickup device includes: a silicon layer; a pixel portion formed in the silicon layer for processing and outputting signal charges obtained by carrying out photoelectric conversion for incident lights; an alignment mark formed in a periphery of the pixel portion and in the silicon layer; and a contact portion through which a first electrode within a wiring layer formed on a first surface of the silicon layer, and a second electrode formed on a second surface opposite to the first surface of the silicon layer through an insulating film are connected, wherein the alignment mark and the contact portion are formed from conductive layers made of the same conductive material and formed within respective holes each extending completely through the silicon layer through respective insulating layers made of the same material.

Abstract: An automatic or semiautomatic method of assembly of radiation digital imaging tiles to form a one or two dimensional imaging panel whereby the imaging tiles are provided with alignment mark(s), inherent or specific, and a mother board or substrate is also provide with alignment mark(s) and the imaging tiles are mounted on the mother board by means of mechanical pick and place mechanism, whereby the distances of corresponding alignment mark are set to predetermined values, programmed in the automatic machine.

Abstract: A semiconductor apparatus includes a semiconductor substrate having a main surface, a multilayer structure circuit formed over the main surface of the semiconductor substrate, a protective wall formed in the same layer as an uppermost layer of the multilayer structure circuit so as to surround the multilayer structure circuit in plan view, and an alignment mark formed in the same layer as the uppermost layer. The alignment mark is formed so as to contact at least part of the protective wall.

Abstract: A semiconductor substrate is provided in which an alignment mark is formed that can be used for an alignment even after the formation of an impurity diffused layer by the planarization of an epitaxial film. A trench is formed in an alignment region of an N+-type substrate. This trench is used to leave voids after the formation of an N?-type layer. Then, the voids formed in the N+-type substrate can be used as an alignment mark. Thus, such a semiconductor substrate can be used to provide an alignment in the subsequent step of manufacturing the semiconductor apparatus. Thus, the respective components constituting the semiconductor apparatus can be formed at desired positions accurately.

Abstract: A method for aligning a photolithographic machine in an automated semiconductor manufacturing system is provided. The method may include identifying a maximum precision degree for a wafer and identifying a maximum overlay correction value. The method may simulate one or more algorithms to determine whether an algorithm aligns a leading lot within alignment specifications. The method may align a photolithography machine using an algorithm selected based on the simulations.

Abstract: A semiconductor device and a method of fabricating the semiconductor device is provided. In the method, a semiconductor substrate defining a device region and an outer region at a periphery of the device region is provided, an align trench is formed in the outer region, a dummy trench is formed in the device region, an epi layer is formed over a top surface of the semiconductor substrate and within the dummy trench, a current path changing part is formed over the epi layer, and a gate electrode is formed over the current path changing part. When the epi layer is formed, a current path changing trench corresponding to the dummy trench is formed over the epi layer, and the current path changing part is formed within the current path changing trench.

Abstract: A stacking apparatus that stacks chip assemblies each having a plurality of chips disposed continuously with circuit patterns and electrodes, includes: a plurality of stages each allowed to move arbitrarily, on which the chip assemblies are placed; a storage unit that stores an estimated extent of change in a position of an electrode at each chip, expected to occur as heat is applied to the chip assemblies placed on the plurality of stages during a stacking process; and a control unit that sets positions of the plurality of stages to be assumed relative to each other during the stacking process based upon the estimated extent of change in the position of the electrode at each chip provided from the storage unit and position information indicating positions of individual chips formed at the chip assemblies and controls at least one of the plurality of stages.

Abstract: The invention relates to production of alignment marks on a semiconductor wafer with the use of a light-opaque layer (17), wherein, before the light-opaque layer (17) is applied, by means of the etching of cavities, free-standing pillar groups are produced in the cavities and then the light-opaque layer (17) is applied. The pillars are produced with a height of above 1 ?m, which, moreover, is greater than a thickness of the light-opaque layer (17) to be applied in the cavities as layer portions (17x; 17y). The cavities are formed with a width such that they are filled only partly with the layer portions (17x; 17y) when the light-opaque layer (17) is applied. The high, freely positioned alignment marks produced by the method as pillar series (16x; 16y), having a plurality of individual pillars (16a; 16a?) in a cavity (12a, 12y), of a scribing trench on the semiconductor wafer are likewise described.

Abstract: A patterning slit sheet assembly for performing a deposition process to form a thin film on a substrate in a desired fine pattern. The patterning slit sheet assembly includes a patterning slit sheet having a plurality of slits, a frame combined with the patterning slit sheet to support the patterning slit sheet, and a support unit including an upper member that is allowed to be moved or fixed to support the patterning slit sheet when a gravitational force is applied to the patterning slit sheet and a lower member disposed more apart from the patterning slit sheet than the upper member, wherein the upper member is fixed on the lower member.

Abstract: A method for producing a semiconductor layer is disclosed. One embodiment provides for a semiconductor layer on a semiconductor substrate containing oxygen. Crystal defects are produced at least in a near-surface region of the semiconductor substrate. A thermal process is carried out wherein the oxygen is taken up at the crystal defects. The semiconductor layer is deposited epitaxially over the near-surface region of the semiconductor substrate.

Abstract: Methods of manufacturing a semiconductor device are provided. The method includes forming a preliminary mask pattern on an etch target layer. The preliminary mask pattern includes wave line type patterns, and each of the wave line type patterns includes main pattern portions and connection bar pattern portions. Node separation walls are formed on sidewalls of the preliminary mask patterns. The etch target layer is etched using the node separation walls as etch masks to form through holes penetrating the etch target layer. Nodes are formed in respective ones of the through holes.

Abstract: A substrate comprises a first mark and a second mark. The first mark comprises a first pattern with at least one mark feature formed by a first material and at least one region formed by a second material. The first and second materials have different material characteristics with respect to a substrate treatment process such that a step height in a direction substantially perpendicular to the surface of the substrate may be created by applying the substrate treatment process. The second mark can be provided with a second step height by applying the substrate treatment process. The second step height is substantially different from the first step height.

Abstract: Provided is an apparatus that includes an overlay mark. The overlay mark includes a first portion that includes a plurality of first features. Each of the first features have a first dimension measured in a first direction and a second dimension measured in a second direction that is approximately perpendicular to the first direction. The second dimension is greater than the first dimension. The overlay mark also includes a second portion that includes a plurality of second features. Each of the second features have a third dimension measured in the first direction and a fourth dimension measured in the second direction. The fourth dimension is less than the third dimension. At least one of the second features is partially surrounded by the plurality of first features in both the first and second directions.

Abstract: A method comprises providing a semiconductor substrate having a first layer and a second layer above the first layer. The first layer haw a plurality of first patterns, vias or contacts. The second layer has second patterns corresponding to the first patterns, vias or contacts. The second patterns have a plurality of in-plane offsets relative to the corresponding first patterns, vias or contacts. A scanning electron microscope is used to measure line edge roughness (LER) values of the second patterns. An overlay error is calculated between the first and second layers based on the measured LER values.

Abstract: A method for manufacturing an electronic device, including a step of aligning and stacking a plurality of substrates, each of the plurality of substrates having a plurality of vertical conductors and magnetic films, the vertical conductors being directed along a thickness direction of the substrate and distributed in a row with respect to a substrate surface, the magnetic films being disposed in place on the substrate surface in a predetermined positional relationship with the vertical conductors, upon aligning the plurality of substrates, the electronic device manufacturing method including a step of applying an external magnetic field to produce a magnetic attractive force between the magnetic films of adjacent stacked substrates and align the vertical conductors by the magnetic attractive force.

Abstract: A method for forming a magnetic tunnel junction cell includes forming a pinning layer, a pinned layer, a dielectric layer and a free layer over a first electrode, forming a second electrode on the free layer, etching the free layer and the dielectric layer using the second electrode as an etch barrier to form a first pattern, forming a prevention layer on a sidewall of the first pattern, and etching the pinned layer and the pinning layer using the second electrode and the prevention layer as an etch barrier to form a second pattern.

Abstract: System and method for automated semiconductor manufacturing is provided. In accordance with one aspect of the present invention, a system for automated semiconductor wafer manufacturing includes a smart overlay control (SOC) database having empirical alignment data related to overlay alignment, and a simulation module communicatively coupled to the SOC database, the simulation module determining a simulated overlay alignment of a wafer on the plurality of photolithography tools in a tool bank based on the empirical alignment data stored in the SOC database. The system also includes a dispatch module communicatively coupled to the SOC database and the simulation module, the dispatch module controlling the dispatch of a wafer to one of a plurality of photolithography tools in a tool bank based at least in part on the simulated overlay alignment.

Abstract: A stacking apparatus that stacks chip assemblies each having a plurality of chips disposed continuously with circuit patterns and electrodes, includes: a plurality of stages each allowed to move arbitrarily, on which the chip assemblies are placed; a storage unit that stores an estimated extent of change in a position of an electrode at each chip, expected to occur as heat is applied to the chip assemblies placed on the plurality of stages during a stacking process; and a control unit that sets positions of the plurality of stages to be assumed relative to each other during the stacking process based upon the estimated extent of change in the position of the electrode at each chip provided from the storage unit and position information indicating positions of individual chips formed at the chip assemblies and controls at least one of the plurality of stages.

Abstract: Methods of semiconductor device fabrication are disclosed. An exemplary method includes processes of depositing a first pattern on a semiconductor substrate, wherein the first pattern defines wide and narrow spaces; depositing spacer material over the first pattern on the substrate; etching the spacer material such that the spacer material is removed from horizontal surfaces of the substrate and the first pattern but remains adjacent to vertical surfaces of a wide space defined by the first pattern and remains within narrow a space defined by the first pattern; and removing the first pattern from the substrate. In one embodiment, the first pattern can comprise sacrificial material, which can include, for example, polysilicon material. The deposition can comprise physical vapor deposition, chemical vapor deposition, electrochemical deposition, molecular beam epitaxy, atomic layer deposition or other deposition techniques.

Abstract: A method for aligning a wafer stack includes providing a wafer stack including a top wafer with a top mark and a bottom wafer with a bottom mark in particular the top mark and the bottom mark capable of corresponding to each other; adjusting a relative position between the top wafer and the bottom wafer so that the top mark and the bottom mark are in contact with each other; applying an electrical signal on the top mark to obtain an electrical reading and optimizing the electrical reading to substantially align the wafer stack.

Abstract: Mark and method for integrated circuit fabrication with polarized light lithography. A preferred embodiment comprises a first plurality of elements comprised of a first component type, wherein the first component type has a first polarization, and a second plurality of elements comprised of a second component type, wherein the second component type has a second polarization, wherein the first polarization and the second polarization are orthogonal, wherein adjacent elements are of different component types. The alignment marks can be used in an intensity based or a diffraction based alignment process.

Abstract: A wafer includes an active region and a kerf region surrounding at least a portion of the active region. The wafer also includes a target region having a rectangular shape with a width and a length greater than the width, the target region including one or more target patterns, at least one of the target patterns being formed by two sub-patterns disposed at opposing corners of a target rectangle disposable within the target region.

Abstract: In order to solve the above problem, provided is an electronic component having an authentication pattern formed on an exposed surface, in which the authentication pattern includes a base section including a resin and colored particles having a hue that can be identified in the base section, and the colored particles are dispersed so as to form dotted pattern in the base section.

Abstract: A system and method for providing an active array of temperature sensing and cooling elements, including an active heatsink which further includes an active temperature sensing layer, a thermoelectric cooling layer, and a heatsink, which further includes a plurality of cooling channels. The temperature sensing element within the active temperature sensing layer includes a plurality of switching transistors, a linear transistor, a current sense resistor, a thermistor, a voltage sensing bus, a voltage setting bus, a current measurement bus, a measurement switching bus, a sense control bus, a storage capacitor, and a supply voltage, all under the control of a process control computer. The method of using an active array of temperature sensing and cooling elements includes the steps of aligning the shadow mask, depositing the material, detecting a thermal gradient, and controlling the thermoelectric cooling.

Abstract: The present invention relates generally to assembly techniques. According to the present invention, the alignment and probing techniques to improve the accuracy of component placement in assembly are described. More particularly, the invention includes methods and structures to detect and improve the component placement accuracy on a target platform by incorporating alignment marks on component and reference marks on target platform under various probing techniques. A set of sensors grouped in any array to form a multiple-sensor probe can detect the deviation of displaced components in assembly.

Abstract: Provided is an apparatus that includes an overlay mark. The overlay mark includes a first portion that includes a plurality of first features. Each of the first features have a first dimension measured in a first direction and a second dimension measured in a second direction that is approximately perpendicular to the first direction. The second dimension is greater than the first dimension. The overlay mark also includes a second portion that includes a plurality of second features. Each of the second features have a third dimension measured in the first direction and a fourth dimension measured in the second direction. The fourth dimension is less than the third dimension. At least one of the second features is partially surrounded by the plurality of first features in both the first and second directions.

Abstract: An IC alignment mark in a contact metal layer for use under an opaque layer, and a process for forming the alignment mark, are disclosed. The alignment mark includes contact metal fields, each several microns wide, with an array of PMD pillars in the interior, formed during contact etch, contact metal deposition and selective contact metal removal processes. The pillars are arrayed such that all exposed surfaces of the contact metal are planar. One configuration is a rectangular array in which every other row is laterally offset by one-half of the column spacing. Horizontal dimensions of the pillars are selected to maximize the contact metal fill factor, while providing sufficient adhesion to the underlying substrate during processing. The contact metal is at least 15 nanometers lower than the PMD layer surrounding the alignment mark, as a result of the contact metal removal process.

Abstract: The symbolization of a semiconductor device (100) is incorporated in a thin sheet (130) attached to the top of the device, facing outwardly with its bare surface. The material of the sheet (about 1 to 10 ?m thick) includes regions of a first optical reflectivity and a first color, and regions (133) of a second optical reflectivity and a second color, which differ from, and contrast with, the first reflectivity and color. Preferred choices for the sheet material include the compound o-cresol novolac epoxy and the compound bisphenol-A, more preferably with the chemical imidazole added to the film material. A preferred embodiment of the invention is a packaged device with a semiconductor chip a (101) connected to a substrate (102); the connection is achieved by bonding wires (111) forming an arch with a top 111a. The chip, the wire arches, and the substrate are embedded in an encapsulation material (120), which borders on the attached top sheet so that the arch tops touch the border (131).

Abstract: Methods of forming substrates having two-sided microstructures therein include selectively etching a first surface of the substrate to define a plurality of alignment keys therein that extend through the substrate to a second surface thereof. A direct photolithographic alignment step is then performed on a second surface of the substrate by aligning a photolithography mask to the plurality of alignment keys at the second surface. This direct alignment step is performed during steps to photolithographically define patterns in the second surface.

Abstract: A semiconductor substrate has a plurality of groove portions formed along scribe lines. The semiconductor substrate includes: insulating layers formed in the plurality of groove portions; a rectangular unit region in contact with at least any one of the plurality of groove portions; and a wiring electrode including an extended terminal portion extended from the unit region to the inside of the groove portion. The semiconductor substrate is manufactured by forming a plurality of groove portions along scribe lines; embedding an insulating material in the plurality of groove portions and planarizing a surface to form insulating layers; and forming a wiring electrode including an extended terminal portion extended from a rectangular unit region in contact with at least any one of the plurality of groove portions to the inside of the groove portion.

Abstract: In a method of manufacturing an ink jet print head that includes a number of aligned modules, an alignment mark is foamed on a first and a second adjacent module, wherein the alignment mark is positioned on a boundary between the first and the second adjacent module along which the wafer is to be separated. In a separating step the wafer is separated into separate modules such that the alignment mark is divided over said first and second adjacent module. At least one of said first and second module is aligned by reference to the divided alignment mark The method improves the accuracy, with which the modules can be aligned.

Abstract: An IC alignment mark in a contact metal layer for use under an opaque layer, and a process for forming the alignment mark, are disclosed. The alignment mark includes contact metal fields, each several microns wide, with an array of PMD pillars in the interior, formed during contact etch, contact metal deposition and selective contact metal removal processes. The pillars are arrayed such that all exposed surfaces of the contact metal are planar. One configuration is a rectangular array in which every other row is laterally offset by one-half of the column spacing. Horizontal dimensions of the pillars are selected to maximize the contact metal fill factor, while providing sufficient adhesion to the underlying substrate during processing. The contact metal is at least 15 nanometers lower than the PMD layer surrounding the alignment mark, as a result of the contact metal removal process.

Abstract: A solid-state image pickup device includes: a silicon layer; a pixel portion formed in the silicon layer for processing and outputting signal charges obtained by carrying out photoelectric conversion for incident lights; an alignment mark formed in a periphery of the pixel portion and in the silicon layer; and a contact portion through which a first electrode within a wiring layer formed on a first surface of the silicon layer, and a second electrode formed on a second surface opposite to the first surface of the silicon layer through an insulating film are connected, wherein the alignment mark and the contact portion are formed from conductive layers made of the same conductive material and formed within respective holes each extending completely through the silicon layer through respective insulating layers made of the same material.

Abstract: A chip package is disclosed. The package includes a carrier substrate and at least two semiconductor chips thereon. Each semiconductor chip includes a plurality of conductive pads. A position structure is disposed on the carrier substrate to fix locations of the semiconductor chips at the carrier substrate. A fill material layer is formed on the carrier substrate, covers the semiconductor chips and the position structure, and has a plurality of openings correspondingly exposing the conductive pads. A redistribution layer (RDL) is disposed on the fill material layer and is connected to the conductive pads through the plurality of openings. A protective layer covers the fill material layer and the RDL. A plurality of conductive bumps is disposed on the protective layer and is electrically connected to the RDL. A fabrication method of the chip package is also disclosed.

Abstract: Mark and method for integrated circuit fabrication with polarized light lithography. A preferred embodiment comprises a first plurality of elements comprised of a first component type, wherein the first component type has a first polarization, and a second plurality of elements comprised of a second component type, wherein the second component type has a second polarization, wherein the first polarization and the second polarization are orthogonal, wherein adjacent elements are of different component types. The alignment marks can be used in an intensity based or a diffraction based alignment process.

Abstract: A stacking apparatus that stacks chip assemblies each having a plurality of chips disposed continuously with circuit patterns and electrodes, includes: a plurality of stages each allowed to move arbitrarily, on which the chip assemblies are placed; a storage unit that stores an estimated extent of change in a position of an electrode at each chip, expected to occur as heat is applied to the chip assemblies placed on the plurality of stages during a stacking process; and a control unit that sets positions of the plurality of stages to be assumed relative to each other during the stacking process based upon the estimated extent of change in the position of the electrode at each chip provided from the storage unit and position information indicating positions of individual chips formed at the chip assemblies and controls at least one of the plurality of stages.

Abstract: An automatic or semiautomatic method of assembly of radiation digital imaging tiles to form a one or two dimensional imaging panel whereby the imaging tiles are provided with alignment mark(s), inherent or specific, and a mother board or substrate is also provide with alignment mark(s) and the imaging tiles are mounted on the mother board by means of mechanical pick and place mechanism, whereby the distances of corresponding alignment mark are set to predetermined values, programmed in the automatic machine.

Abstract: A method of forming a semiconductor device includes the following processes. A first groove is formed in a semiconductor substrate. An insulating film is formed in the first groove. An interlayer insulating film is formed over the semiconductor substrate. A removing process is performed to remove a part of the interlayer insulating film and a part of the insulating film to form an alignment mark in the first groove.

Abstract: A display substrate includes a signal line, a thin-film transistor (“TFT”), a key pattern, a light-blocking pattern, a color filter, a pixel electrode and an alignment key. The signal line and the key pattern are formed on a substrate. The TFT is electrically connected to the signal line. The light-blocking pattern is formed on the substrate and covers the signal line, the TFT and the key pattern. The color filter is formed in a unit pixel area of the substrate. The pixel electrode is formed on the color filter and is electrically connected to the TFT. The alignment key is formed on the light-blocking pattern, and a position of the alignment key on the substrate corresponds to a position of the key pattern on the substrate.

Abstract: A circuit pattern having a size finer than a half of a wavelength of an exposure beam is transferred on a semiconductor wafer plane with an excellent accuracy by means of a mask whereupon an integrated circuit pattern is formed and a reduction projection aligner. The accuracy of transferring the circuit pattern on the semiconductor wafer is improved by synergic effects of super-resolution exposure, wherein a mask cover made of a transparent medium is provided on a pattern side of the integrated circuit mask so as to suppress the aberration of reduction projection alignment, and a method of increasing the number of actual apertures of the optical reduction projection lens system provided with the wafer cover made of the transparent medium on a photoresist side of the semiconductor wafer to which planarizing process is performed.

Abstract: In a method of manufacturing a complementary metal-oxide semiconductor (CMOS) image sensor (CIS), an epitaxial layer may be formed on a first substrate including a chip area and a scribe lane area. A first impurity layer may be formed adjacent to the first substrate by implanting first impurities into the epitaxial layer. A photodiode may be formed in the epitaxial layer on the chip area. A circuit element electrically connected to the photodiode may be formed on the epitaxial layer. A protective layer protecting the circuit element may be formed on the epitaxial layer. A second substrate may be attached onto the protective layer. The first substrate may be removed to expose the epitaxial layer. A color filter layer may be formed on the exposed epitaxial layer using the first impurity layer as an alignment key. A microlens may be formed over the color filter layer.

Abstract: A method of manufacturing a semiconductor device, includes forming a structure wherein a first alignment mark is provided in a first alignment-mark arrangement area of a first layer, a second alignment mark is provided in a second alignment-mark arrangement area of a second layer, a dummy pattern is provided above the first alignment-mark arrangement area, and substantially no dummy pattern is provided above the second alignment-mark arrangement area, and aligning a third layer provided above the structure by using the second alignment mark.

Abstract: There is disclosed a manufacturing method for exposure mask, which comprises acquiring a first information showing surface shape of surface of each of a plurality of mask substrates, and a second information showing the flatness of the surface of each of mask substrates before and after chucked on a mask stage of an exposure apparatus, forming a corresponding relation of each mask substrate, the first information and the second information, selecting the second information showing a desired flatness among the second information of the corresponding relation, and preparing another mask substrate having the same surface shape as the surface shape indicated by the first information in the corresponding relation with the selected second information, and forming a desired pattern on the above-mentioned another mask substrate.